Litcius/Paper detail

Low-pressure-induced giant barocaloric effect in an all-<i>d</i>-metal Heusler Ni35.5Co14.5Mn35Ti15 magnetic shape memory alloy

Zhiyang Wei, Yi Shen, Zhe Zhang, Jianping Guo, Bing Li, Enke Liu, Zhidong Zhang, Jian Liu

2020APL Materials69 citationsDOIOpen Access PDF

Abstract

The clean and energy-efficient solid-state refrigeration based on magnetostructural phase transformation is a promising alternative technology for vapor-compression refrigeration. Herein, using a unique quasi-direct calorimetric method in a high hydrostatic pressure condition, we have studied the barocaloric effect for a Ni35.5Co14.5Mn35Ti15 all-d-metal Heusler alloy that undergoes a martensitic transformation accompanied by a large magnetization change. The martensitic transformation is found to be sensitive to either applied pressure or magnetic field with the large transformation temperature driving rates of 5.8 K kbar−1 and 2.0 K T−1. Such a sensitive response to external stimuli originates from the large lattice/volume- and magnetization-discontinuity on the phase transformation. The Ni35.5Co14.5Mn35Ti15 alloy exhibits a large barocaloric effect with an isothermal entropy change of −24.2 J kg−1 K−1and an adiabatic temperature change of 4.2 K, concomitant with a relatively low pressure change of 1 kbar, appearing to be the largest values among those of reported magnetic shape memory alloys. Moreover, by virtue of the strong magnetostructural coupling in the Ni35.5Co14.5Mn35Ti15 alloy, we propose a strategy of applying/releasing pressure and magnetic field in a proper sequence to eliminate the hysteresis and effectively enhance the reproducibility of the barocaloric effect.

Topics & Concepts

Materials scienceMagnetic refrigerationCondensed matter physicsMagnetic shape-memory alloyAlloyDiffusionless transformationAdiabatic processShape-memory alloyMagnetizationMagnetic fieldHydrostatic pressureThermodynamicsAmbient pressureMartensiteMetallurgyMagnetic anisotropyMicrostructureQuantum mechanicsPhysicsShape Memory Alloy TransformationsMagnetic and transport properties of perovskites and related materialsCreativity in Education and Neuroscience